/*
 * Python Perf Trampoline Support - JIT Dump Implementation
 *
 * This file implements the perf jitdump API for Python's performance profiling
 * integration. It allows perf (Linux performance analysis tool) to understand
 * and profile dynamically generated Python bytecode by creating JIT dump files
 * that perf can inject into its analysis.
 *
 *
 * IMPORTANT: This file exports specific callback functions that are part of
 * Python's internal API. Do not modify the function signatures or behavior
 * of exported functions without coordinating with the Python core team.
 *
 * Usually the binary and libraries are mapped in separate region like below:
 *
 *   address ->
 *    --+---------------------+--//--+---------------------+--
 *      | .text | .data | ... |      | .text | .data | ... |
 *    --+---------------------+--//--+---------------------+--
 *          myprog                      libc.so
 *
 * So it'd be easy and straight-forward to find a mapped binary or library from an
 * address.
 *
 * But for JIT code, the code arena only cares about the code section. But the
 * resulting DSOs (which is generated by perf inject -j) contain ELF headers and
 * unwind info too. Then it'd generate following address space with synthesized
 * MMAP events. Let's say it has a sample between address B and C.
 *
 *                                                sample
 *                                                  |
 *   address ->                         A       B   v   C
 *   ---------------------------------------------------------------------------------------------------
 *   /tmp/jitted-PID-0.so   | (headers) | .text | unwind info |
 *   /tmp/jitted-PID-1.so           | (headers) | .text | unwind info |
 *   /tmp/jitted-PID-2.so                   | (headers) | .text | unwind info |
 *     ...
 *   ---------------------------------------------------------------------------------------------------
 *
 * If it only maps the .text section, it'd find the jitted-PID-1.so but cannot see
 * the unwind info. If it maps both .text section and unwind sections, the sample
 * could be mapped to either jitted-PID-0.so or jitted-PID-1.so and it's confusing
 * which one is right. So to make perf happy we have non-overlapping ranges for each
 * DSO:
 *
 *   address ->
 *   -------------------------------------------------------------------------------------------------------
 *   /tmp/jitted-PID-0.so   | (headers) | .text | unwind info |
 *   /tmp/jitted-PID-1.so                         | (headers) | .text | unwind info |
 *   /tmp/jitted-PID-2.so                                               | (headers) | .text | unwind info |
 *     ...
 *   -------------------------------------------------------------------------------------------------------
 *
 * As the trampolines are constant, we add a constant padding but in general the padding needs to have the
 * size of the unwind info rounded to 16 bytes. In general, for our trampolines this is 0x50
 */



#include "Python.h"
#include "pycore_ceval.h"         // _PyPerf_Callbacks
#include "pycore_frame.h"
#include "pycore_interp.h"
#include "pycore_runtime.h"       // _PyRuntime

#ifdef PY_HAVE_PERF_TRAMPOLINE

/* Standard library includes for perf jitdump implementation */
#if defined(__linux__)
#  include <elf.h>                // ELF architecture constants
#endif
#include <fcntl.h>                // File control operations
#include <stdio.h>                // Standard I/O operations
#include <stdlib.h>               // Standard library functions
#include <sys/mman.h>             // Memory mapping functions (mmap)
#include <sys/types.h>            // System data types
#include <unistd.h>               // System calls (sysconf, getpid)
#include <sys/time.h>             // Time functions (gettimeofday)
#if defined(__linux__)
#  include <sys/syscall.h>        // System call interface
#endif

// =============================================================================
//                           CONSTANTS AND CONFIGURATION
// =============================================================================

/*
 * Memory layout considerations for perf jitdump:
 *
 * Perf expects non-overlapping memory regions for each JIT-compiled function.
 * When perf processes the jitdump file, it creates synthetic DSO (Dynamic
 * Shared Object) files that contain:
 * - ELF headers
 * - .text section (actual machine code)
 * - Unwind information (for stack traces)
 *
 * To ensure proper address space layout, we add padding between code regions.
 * This prevents address conflicts when perf maps the synthesized DSOs.
 *
 * Memory layout example:
 * /tmp/jitted-PID-0.so: [headers][.text][unwind_info][padding]
 * /tmp/jitted-PID-1.so:                                       [headers][.text][unwind_info][padding]
 *
 * The padding size is now calculated automatically during initialization
 * based on the actual unwind information requirements.
 */


/* These constants are defined inside <elf.h>, which we can't use outside of linux. */
#if !defined(__linux__)
#  if defined(__i386__) || defined(_M_IX86)
#    define EM_386      3
#  elif defined(__arm__) || defined(_M_ARM)
#    define EM_ARM      40
#  elif defined(__x86_64__) || defined(_M_X64)
#    define EM_X86_64   62
#  elif defined(__aarch64__)
#    define EM_AARCH64  183
#  elif defined(__riscv)
#    define EM_RISCV    243
#  endif
#endif

/* Convenient access to the global trampoline API state */
#define trampoline_api _PyRuntime.ceval.perf.trampoline_api

/* Type aliases for clarity and portability */
typedef uint64_t uword;                    // Word-sized unsigned integer
typedef const char* CodeComments;          // Code comment strings

/* Memory size constants */
#define MB (1024 * 1024)                   // 1 Megabyte for buffer sizing

// =============================================================================
//                        ARCHITECTURE-SPECIFIC DEFINITIONS
// =============================================================================

/*
 * Returns the ELF machine architecture constant for the current platform.
 * This is required for the jitdump header to correctly identify the target
 * architecture for perf processing.
 *
 */
static uint64_t GetElfMachineArchitecture(void) {
#if defined(__x86_64__) || defined(_M_X64)
    return EM_X86_64;
#elif defined(__i386__) || defined(_M_IX86)
    return EM_386;
#elif defined(__aarch64__)
    return EM_AARCH64;
#elif defined(__arm__) || defined(_M_ARM)
    return EM_ARM;
#elif defined(__riscv)
    return EM_RISCV;
#else
    Py_UNREACHABLE();  // Unsupported architecture - should never reach here
    return 0;
#endif
}

// =============================================================================
//                           PERF JITDUMP DATA STRUCTURES
// =============================================================================

/*
 * Perf jitdump file format structures
 *
 * These structures define the binary format that perf expects for JIT dump files.
 * The format is documented in the Linux perf tools source code and must match
 * exactly for proper perf integration.
 */

/*
 * Jitdump file header - written once at the beginning of each jitdump file
 * Contains metadata about the process and jitdump format version
 */
typedef struct {
    uint32_t magic;              // Magic number (0x4A695444 = "JiTD")
    uint32_t version;            // Jitdump format version (currently 1)
    uint32_t size;               // Size of this header structure
    uint32_t elf_mach_target;    // Target architecture (from GetElfMachineArchitecture)
    uint32_t reserved;           // Reserved field (must be 0)
    uint32_t process_id;         // Process ID of the JIT compiler
    uint64_t time_stamp;         // Timestamp when jitdump was created
    uint64_t flags;              // Feature flags (currently unused)
} Header;

/*
 * Perf event types supported by the jitdump format
 * Each event type has a corresponding structure format
 */
enum PerfEvent {
    PerfLoad = 0,           // Code load event (new JIT function)
    PerfMove = 1,           // Code move event (function relocated)
    PerfDebugInfo = 2,      // Debug information event
    PerfClose = 3,          // JIT session close event
    PerfUnwindingInfo = 4   // Stack unwinding information event
};

/*
 * Base event structure - common header for all perf events
 * Every event in the jitdump file starts with this structure
 */
struct BaseEvent {
    uint32_t event;         // Event type (from PerfEvent enum)
    uint32_t size;          // Total size of this event including payload
    uint64_t time_stamp;    // Timestamp when event occurred
};

/*
 * Code load event - indicates a new JIT-compiled function is available
 * This is the most important event type for Python profiling
 */
typedef struct {
    struct BaseEvent base;   // Common event header
    uint32_t process_id;     // Process ID where code was generated
#if defined(__APPLE__)
    uint64_t thread_id;      // Thread ID where code was generated
#else
    uint32_t thread_id;      // Thread ID where code was generated
#endif
    uint64_t vma;            // Virtual memory address where code is loaded
    uint64_t code_address;   // Address of the actual machine code
    uint64_t code_size;      // Size of the machine code in bytes
    uint64_t code_id;        // Unique identifier for this code region
    /* Followed by:
     * - null-terminated function name string
     * - raw machine code bytes
     */
} CodeLoadEvent;

/*
 * Code unwinding information event - provides DWARF data for stack traces
 * Essential for proper stack unwinding during profiling
 */
typedef struct {
    struct BaseEvent base;      // Common event header
    uint64_t unwind_data_size;  // Size of the unwinding data
    uint64_t eh_frame_hdr_size; // Size of the EH frame header
    uint64_t mapped_size;       // Total mapped size (with padding)
    /* Followed by:
     * - EH frame header
     * - DWARF unwinding information
     * - Padding to alignment boundary
     */
} CodeUnwindingInfoEvent;

// =============================================================================
//                              GLOBAL STATE MANAGEMENT
// =============================================================================

/*
 * Global state for the perf jitdump implementation
 *
 * This structure maintains all the state needed for generating jitdump files.
 * It's designed as a singleton since there's typically only one jitdump file
 * per Python process.
 */
typedef struct {
    FILE* perf_map;          // File handle for the jitdump file
    PyThread_type_lock map_lock;  // Thread synchronization lock
    void* mapped_buffer;     // Memory-mapped region (signals perf we're active)
    size_t mapped_size;      // Size of the mapped region
    int code_id;             // Counter for unique code region identifiers
} PerfMapJitState;

/* Global singleton instance */
static PerfMapJitState perf_jit_map_state;

// =============================================================================
//                              TIME UTILITIES
// =============================================================================

/* Time conversion constant */
static const intptr_t nanoseconds_per_second = 1000000000;

/*
 * Get current monotonic time in nanoseconds
 *
 * Monotonic time is preferred for event timestamps because it's not affected
 * by system clock adjustments. This ensures consistent timing relationships
 * between events even if the system clock is changed.
 *
 * Returns: Current monotonic time in nanoseconds since an arbitrary epoch
 */
static int64_t get_current_monotonic_ticks(void) {
    struct timespec ts;
    if (clock_gettime(CLOCK_MONOTONIC, &ts) != 0) {
        Py_UNREACHABLE();  // Should never fail on supported systems
        return 0;
    }

    /* Convert to nanoseconds for maximum precision */
    int64_t result = ts.tv_sec;
    result *= nanoseconds_per_second;
    result += ts.tv_nsec;
    return result;
}

/*
 * Get current wall clock time in microseconds
 *
 * Used for the jitdump file header timestamp. Unlike monotonic time,
 * this represents actual wall clock time that can be correlated with
 * other system events.
 *
 * Returns: Current time in microseconds since Unix epoch
 */
static int64_t get_current_time_microseconds(void) {
    struct timeval tv;
    if (gettimeofday(&tv, NULL) < 0) {
        Py_UNREACHABLE();  // Should never fail on supported systems
        return 0;
    }
    return ((int64_t)(tv.tv_sec) * 1000000) + tv.tv_usec;
}

// =============================================================================
//                              UTILITY FUNCTIONS
// =============================================================================

/*
 * Round up a value to the next multiple of a given number
 *
 * This is essential for maintaining proper alignment requirements in the
 * jitdump format. Many structures need to be aligned to specific boundaries
 * (typically 8 or 16 bytes) for efficient processing by perf.
 *
 * Args:
 *   value: The value to round up
 *   multiple: The multiple to round up to
 *
 * Returns: The smallest value >= input that is a multiple of 'multiple'
 */
static size_t round_up(int64_t value, int64_t multiple) {
    if (multiple == 0) {
        return value;  // Avoid division by zero
    }

    int64_t remainder = value % multiple;
    if (remainder == 0) {
        return value;  // Already aligned
    }

    /* Calculate how much to add to reach the next multiple */
    int64_t difference = multiple - remainder;
    int64_t rounded_up_value = value + difference;

    return rounded_up_value;
}

// =============================================================================
//                              FILE I/O UTILITIES
// =============================================================================

/*
 * Write data to the jitdump file with error handling
 *
 * This function ensures that all data is written to the file, handling
 * partial writes that can occur with large buffers or when the system
 * is under load.
 *
 * Args:
 *   buffer: Pointer to data to write
 *   size: Number of bytes to write
 */
static void perf_map_jit_write_fully(const void* buffer, size_t size) {
    FILE* out_file = perf_jit_map_state.perf_map;
    const char* ptr = (const char*)(buffer);

    while (size > 0) {
        const size_t written = fwrite(ptr, 1, size, out_file);
        if (written == 0) {
            Py_UNREACHABLE();  // Write failure - should be very rare
            break;
        }
        size -= written;
        ptr += written;
    }
}

/*
 * Write the jitdump file header
 *
 * The header must be written exactly once at the beginning of each jitdump
 * file. It provides metadata that perf uses to parse the rest of the file.
 *
 * Args:
 *   pid: Process ID to include in the header
 *   out_file: File handle to write to (currently unused, uses global state)
 */
static void perf_map_jit_write_header(int pid, FILE* out_file) {
    Header header;

    /* Initialize header with required values */
    header.magic = 0x4A695444;                    // "JiTD" magic number
    header.version = 1;                           // Current jitdump version
    header.size = sizeof(Header);                 // Header size for validation
    header.elf_mach_target = GetElfMachineArchitecture();  // Target architecture
    header.process_id = pid;                      // Process identifier
    header.time_stamp = get_current_time_microseconds();   // Creation time
    header.flags = 0;                             // No special flags currently used

    perf_map_jit_write_fully(&header, sizeof(header));
}

// =============================================================================
//                              DWARF CONSTANTS AND UTILITIES
// =============================================================================

/*
 * DWARF (Debug With Arbitrary Record Formats) constants
 *
 * DWARF is a debugging data format used to provide stack unwinding information.
 * These constants define the various encoding types and opcodes used in
 * DWARF Call Frame Information (CFI) records.
 */

/* DWARF Call Frame Information version */
#define DWRF_CIE_VERSION 1

/* DWARF CFA (Call Frame Address) opcodes */
enum {
    DWRF_CFA_nop = 0x0,                    // No operation
    DWRF_CFA_offset_extended = 0x5,        // Extended offset instruction
    DWRF_CFA_def_cfa = 0xc,               // Define CFA rule
    DWRF_CFA_def_cfa_register = 0xd,      // Define CFA register
    DWRF_CFA_def_cfa_offset = 0xe,        // Define CFA offset
    DWRF_CFA_offset_extended_sf = 0x11,   // Extended signed offset
    DWRF_CFA_advance_loc = 0x40,          // Advance location counter
    DWRF_CFA_offset = 0x80,               // Simple offset instruction
    DWRF_CFA_restore = 0xc0               // Restore register
};

/* DWARF Exception Handling pointer encodings */
enum {
    DWRF_EH_PE_absptr = 0x00,             // Absolute pointer
    DWRF_EH_PE_omit = 0xff,               // Omitted value

    /* Data type encodings */
    DWRF_EH_PE_uleb128 = 0x01,            // Unsigned LEB128
    DWRF_EH_PE_udata2 = 0x02,             // Unsigned 2-byte
    DWRF_EH_PE_udata4 = 0x03,             // Unsigned 4-byte
    DWRF_EH_PE_udata8 = 0x04,             // Unsigned 8-byte
    DWRF_EH_PE_sleb128 = 0x09,            // Signed LEB128
    DWRF_EH_PE_sdata2 = 0x0a,             // Signed 2-byte
    DWRF_EH_PE_sdata4 = 0x0b,             // Signed 4-byte
    DWRF_EH_PE_sdata8 = 0x0c,             // Signed 8-byte
    DWRF_EH_PE_signed = 0x08,             // Signed flag

    /* Reference type encodings */
    DWRF_EH_PE_pcrel = 0x10,              // PC-relative
    DWRF_EH_PE_textrel = 0x20,            // Text-relative
    DWRF_EH_PE_datarel = 0x30,            // Data-relative
    DWRF_EH_PE_funcrel = 0x40,            // Function-relative
    DWRF_EH_PE_aligned = 0x50,            // Aligned
    DWRF_EH_PE_indirect = 0x80            // Indirect
};

/* Additional DWARF constants for debug information */
enum { DWRF_TAG_compile_unit = 0x11 };
enum { DWRF_children_no = 0, DWRF_children_yes = 1 };
enum {
    DWRF_AT_name = 0x03,         // Name attribute
    DWRF_AT_stmt_list = 0x10,    // Statement list
    DWRF_AT_low_pc = 0x11,       // Low PC address
    DWRF_AT_high_pc = 0x12       // High PC address
};
enum {
    DWRF_FORM_addr = 0x01,       // Address form
    DWRF_FORM_data4 = 0x06,      // 4-byte data
    DWRF_FORM_string = 0x08      // String form
};

/* Line number program opcodes */
enum {
    DWRF_LNS_extended_op = 0,    // Extended opcode
    DWRF_LNS_copy = 1,           // Copy operation
    DWRF_LNS_advance_pc = 2,     // Advance program counter
    DWRF_LNS_advance_line = 3    // Advance line number
};

/* Line number extended opcodes */
enum {
    DWRF_LNE_end_sequence = 1,   // End of sequence
    DWRF_LNE_set_address = 2     // Set address
};

/*
 * Architecture-specific DWARF register numbers
 *
 * These constants define the register numbering scheme used by DWARF
 * for each supported architecture. The numbers must match the ABI
 * specification for proper stack unwinding.
 */
enum {
#ifdef __x86_64__
    /* x86_64 register numbering (note: order is defined by x86_64 ABI) */
    DWRF_REG_AX,    // RAX
    DWRF_REG_DX,    // RDX
    DWRF_REG_CX,    // RCX
    DWRF_REG_BX,    // RBX
    DWRF_REG_SI,    // RSI
    DWRF_REG_DI,    // RDI
    DWRF_REG_BP,    // RBP
    DWRF_REG_SP,    // RSP
    DWRF_REG_8,     // R8
    DWRF_REG_9,     // R9
    DWRF_REG_10,    // R10
    DWRF_REG_11,    // R11
    DWRF_REG_12,    // R12
    DWRF_REG_13,    // R13
    DWRF_REG_14,    // R14
    DWRF_REG_15,    // R15
    DWRF_REG_RA,    // Return address (RIP)
#elif defined(__aarch64__) && defined(__AARCH64EL__) && !defined(__ILP32__)
    /* AArch64 register numbering */
    DWRF_REG_FP = 29,  // Frame Pointer
    DWRF_REG_RA = 30,  // Link register (return address)
    DWRF_REG_SP = 31,  // Stack pointer
#else
#    error "Unsupported target architecture"
#endif
};

/* DWARF encoding constants used in EH frame headers */
static const uint8_t DwarfUData4 = 0x03;     // Unsigned 4-byte data
static const uint8_t DwarfSData4 = 0x0b;     // Signed 4-byte data
static const uint8_t DwarfPcRel = 0x10;      // PC-relative encoding
static const uint8_t DwarfDataRel = 0x30;    // Data-relative encoding

// =============================================================================
//                              ELF OBJECT CONTEXT
// =============================================================================

/*
 * Context for building ELF/DWARF structures
 *
 * This structure maintains state while constructing DWARF unwind information.
 * It acts as a simple buffer manager with pointers to track current position
 * and important landmarks within the buffer.
 */
typedef struct ELFObjectContext {
    uint8_t* p;            // Current write position in buffer
    uint8_t* startp;       // Start of buffer (for offset calculations)
    uint8_t* eh_frame_p;   // Start of EH frame data (for relative offsets)
    uint8_t* fde_p;        // Start of FDE data (for PC-relative calculations)
    uint32_t code_size;    // Size of the code being described
} ELFObjectContext;

/*
 * EH Frame Header structure for DWARF unwinding
 *
 * This structure provides metadata about the DWARF unwinding information
 * that follows. It's required by the perf jitdump format to enable proper
 * stack unwinding during profiling.
 */
typedef struct {
    unsigned char version;           // EH frame version (always 1)
    unsigned char eh_frame_ptr_enc;  // Encoding of EH frame pointer
    unsigned char fde_count_enc;     // Encoding of FDE count
    unsigned char table_enc;         // Encoding of table entries
    int32_t eh_frame_ptr;           // Pointer to EH frame data
    int32_t eh_fde_count;           // Number of FDEs (Frame Description Entries)
    int32_t from;                   // Start address of code range
    int32_t to;                     // End address of code range
} EhFrameHeader;

// =============================================================================
//                              DWARF GENERATION UTILITIES
// =============================================================================

/*
 * Append a null-terminated string to the ELF context buffer
 *
 * Args:
 *   ctx: ELF object context
 *   str: String to append (must be null-terminated)
 *
 * Returns: Offset from start of buffer where string was written
 */
static uint32_t elfctx_append_string(ELFObjectContext* ctx, const char* str) {
    uint8_t* p = ctx->p;
    uint32_t ofs = (uint32_t)(p - ctx->startp);

    /* Copy string including null terminator */
    do {
        *p++ = (uint8_t)*str;
    } while (*str++);

    ctx->p = p;
    return ofs;
}

/*
 * Append a SLEB128 (Signed Little Endian Base 128) value
 *
 * SLEB128 is a variable-length encoding used extensively in DWARF.
 * It efficiently encodes small numbers in fewer bytes.
 *
 * Args:
 *   ctx: ELF object context
 *   v: Signed value to encode
 */
static void elfctx_append_sleb128(ELFObjectContext* ctx, int32_t v) {
    uint8_t* p = ctx->p;

    /* Encode 7 bits at a time, with continuation bit in MSB */
    for (; (uint32_t)(v + 0x40) >= 0x80; v >>= 7) {
        *p++ = (uint8_t)((v & 0x7f) | 0x80);  // Set continuation bit
    }
    *p++ = (uint8_t)(v & 0x7f);  // Final byte without continuation bit

    ctx->p = p;
}

/*
 * Append a ULEB128 (Unsigned Little Endian Base 128) value
 *
 * Similar to SLEB128 but for unsigned values.
 *
 * Args:
 *   ctx: ELF object context
 *   v: Unsigned value to encode
 */
static void elfctx_append_uleb128(ELFObjectContext* ctx, uint32_t v) {
    uint8_t* p = ctx->p;

    /* Encode 7 bits at a time, with continuation bit in MSB */
    for (; v >= 0x80; v >>= 7) {
        *p++ = (char)((v & 0x7f) | 0x80);  // Set continuation bit
    }
    *p++ = (char)v;  // Final byte without continuation bit

    ctx->p = p;
}

/*
 * Macros for generating DWARF structures
 *
 * These macros provide a convenient way to write various data types
 * to the DWARF buffer while automatically advancing the pointer.
 */
#define DWRF_U8(x) (*p++ = (x))                                    // Write unsigned 8-bit
#define DWRF_I8(x) (*(int8_t*)p = (x), p++)                       // Write signed 8-bit
#define DWRF_U16(x) (*(uint16_t*)p = (x), p += 2)                 // Write unsigned 16-bit
#define DWRF_U32(x) (*(uint32_t*)p = (x), p += 4)                 // Write unsigned 32-bit
#define DWRF_ADDR(x) (*(uintptr_t*)p = (x), p += sizeof(uintptr_t)) // Write address
#define DWRF_UV(x) (ctx->p = p, elfctx_append_uleb128(ctx, (x)), p = ctx->p) // Write ULEB128
#define DWRF_SV(x) (ctx->p = p, elfctx_append_sleb128(ctx, (x)), p = ctx->p) // Write SLEB128
#define DWRF_STR(str) (ctx->p = p, elfctx_append_string(ctx, (str)), p = ctx->p) // Write string

/* Align to specified boundary with NOP instructions */
#define DWRF_ALIGNNOP(s)                                          \
    while ((uintptr_t)p & ((s)-1)) {                              \
        *p++ = DWRF_CFA_nop;                                       \
    }

/* Write a DWARF section with automatic size calculation */
#define DWRF_SECTION(name, stmt)                                  \
    {                                                             \
        uint32_t* szp_##name = (uint32_t*)p;                      \
        p += 4;                                                   \
        stmt;                                                     \
        *szp_##name = (uint32_t)((p - (uint8_t*)szp_##name) - 4); \
    }

// =============================================================================
//                              DWARF EH FRAME GENERATION
// =============================================================================

static void elf_init_ehframe(ELFObjectContext* ctx);

/*
 * Initialize DWARF .eh_frame section for a code region
 *
 * The .eh_frame section contains Call Frame Information (CFI) that describes
 * how to unwind the stack at any point in the code. This is essential for
 * proper profiling as it allows perf to generate accurate call graphs.
 *
 * The function generates two main components:
 * 1. CIE (Common Information Entry) - describes calling conventions
 * 2. FDE (Frame Description Entry) - describes specific function unwinding
 *
 * Args:
 *   ctx: ELF object context containing code size and buffer pointers
 */
static size_t calculate_eh_frame_size(void) {
    /* Calculate the EH frame size for the trampoline function */
    extern void *_Py_trampoline_func_start;
    extern void *_Py_trampoline_func_end;

    size_t code_size = (char*)&_Py_trampoline_func_end - (char*)&_Py_trampoline_func_start;

    ELFObjectContext ctx;
    char buffer[1024];  // Buffer for DWARF data (1KB should be sufficient)
    ctx.code_size = code_size;
    ctx.startp = ctx.p = (uint8_t*)buffer;
    ctx.fde_p = NULL;

    elf_init_ehframe(&ctx);
    return ctx.p - ctx.startp;
}

static void elf_init_ehframe(ELFObjectContext* ctx) {
    uint8_t* p = ctx->p;
    uint8_t* framep = p;  // Remember start of frame data

    /*
    * DWARF Unwind Table for Trampoline Function
    *
    * This section defines DWARF Call Frame Information (CFI) using encoded macros
    * like `DWRF_U8`, `DWRF_UV`, and `DWRF_SECTION` to describe how the trampoline function
    * preserves and restores registers. This is used by profiling tools (e.g., `perf`)
    * and debuggers for stack unwinding in JIT-compiled code.
    *
    * -------------------------------------------------
    * TO REGENERATE THIS TABLE FROM GCC OBJECTS:
    * -------------------------------------------------
    *
    * 1. Create a trampoline source file (e.g., `trampoline.c`):
    *
    *      #include <Python.h>
    *      typedef PyObject* (*py_evaluator)(void*, void*, int);
    *      PyObject* trampoline(void *ts, void *f, int throwflag, py_evaluator evaluator) {
    *          return evaluator(ts, f, throwflag);
    *      }
    *
    * 2. Compile to an object file with frame pointer preservation:
    *
    *      gcc trampoline.c -I. -I./Include -O2 -fno-omit-frame-pointer -mno-omit-leaf-frame-pointer -c
    *
    * 3. Extract DWARF unwind info from the object file:
    *
    *      readelf -w trampoline.o
    *
    *    Example output from `.eh_frame`:
    *
    *      00000000 CIE
    *        Version:               1
    *        Augmentation:          "zR"
    *        Code alignment factor: 4
    *        Data alignment factor: -8
    *        Return address column: 30
    *        DW_CFA_def_cfa: r31 (sp) ofs 0
    *
    *      00000014 FDE cie=00000000 pc=0..14
    *        DW_CFA_advance_loc: 4
    *        DW_CFA_def_cfa_offset: 16
    *        DW_CFA_offset: r29 at cfa-16
    *        DW_CFA_offset: r30 at cfa-8
    *        DW_CFA_advance_loc: 12
    *        DW_CFA_restore: r30
    *        DW_CFA_restore: r29
    *        DW_CFA_def_cfa_offset: 0
    *
    * -- These values can be verified by comparing with `readelf -w` or `llvm-dwarfdump --eh-frame`.
    *
    * ----------------------------------
    * HOW TO TRANSLATE TO DWRF_* MACROS:
    * ----------------------------------
    *
    * After compiling your trampoline with:
    *
    *     gcc trampoline.c -I. -I./Include -O2 -fno-omit-frame-pointer -mno-omit-leaf-frame-pointer -c
    *
    * run:
    *
    *     readelf -w trampoline.o
    *
    * to inspect the generated `.eh_frame` data. You will see two main components:
    *
    *     1. A CIE (Common Information Entry): shared configuration used by all FDEs.
    *     2. An FDE (Frame Description Entry): function-specific unwind instructions.
    *
    * ---------------------
    * Translating the CIE:
    * ---------------------
    * From `readelf -w`, you might see:
    *
    *   00000000 0000000000000010 00000000 CIE
    *     Version:               1
    *     Augmentation:          "zR"
    *     Code alignment factor: 4
    *     Data alignment factor: -8
    *     Return address column: 30
    *     Augmentation data:     1b
    *     DW_CFA_def_cfa: r31 (sp) ofs 0
    *
    * Map this to:
    *
    *     DWRF_SECTION(CIE,
    *         DWRF_U32(0);                             // CIE ID (always 0 for CIEs)
    *         DWRF_U8(DWRF_CIE_VERSION);              // Version: 1
    *         DWRF_STR("zR");                         // Augmentation string "zR"
    *         DWRF_UV(4);                             // Code alignment factor = 4
    *         DWRF_SV(-8);                            // Data alignment factor = -8
    *         DWRF_U8(DWRF_REG_RA);                   // Return address register (e.g., x30 = 30)
    *         DWRF_UV(1);                             // Augmentation data length = 1
    *         DWRF_U8(DWRF_EH_PE_pcrel | DWRF_EH_PE_sdata4); // Encoding for FDE pointers
    *
    *         DWRF_U8(DWRF_CFA_def_cfa);              // DW_CFA_def_cfa
    *         DWRF_UV(DWRF_REG_SP);                   // Register: SP (r31)
    *         DWRF_UV(0);                             // Offset = 0
    *
    *         DWRF_ALIGNNOP(sizeof(uintptr_t));       // Align to pointer size boundary
    *     )
    *
    * Notes:
    *   - Use `DWRF_UV` for unsigned LEB128, `DWRF_SV` for signed LEB128.
    *   - `DWRF_REG_RA` and `DWRF_REG_SP` are architecture-defined constants.
    *
    * ---------------------
    * Translating the FDE:
    * ---------------------
    * From `readelf -w`:
    *
    *   00000014 0000000000000020 00000018 FDE cie=00000000 pc=0000000000000000..0000000000000014
    *     DW_CFA_advance_loc: 4
    *     DW_CFA_def_cfa_offset: 16
    *     DW_CFA_offset: r29 at cfa-16
    *     DW_CFA_offset: r30 at cfa-8
    *     DW_CFA_advance_loc: 12
    *     DW_CFA_restore: r30
    *     DW_CFA_restore: r29
    *     DW_CFA_def_cfa_offset: 0
    *
    * Map the FDE header and instructions to:
    *
    *     DWRF_SECTION(FDE,
    *         DWRF_U32((uint32_t)(p - framep));       // Offset to CIE (relative from here)
    *         DWRF_U32(pc_relative_offset);           // PC-relative location of the code (calculated dynamically)
    *         DWRF_U32(ctx->code_size);               // Code range covered by this FDE
    *         DWRF_U8(0);                             // Augmentation data length (none)
    *
    *         DWRF_U8(DWRF_CFA_advance_loc | 1);      // Advance location by 1 unit (1 * 4 = 4 bytes)
    *         DWRF_U8(DWRF_CFA_def_cfa_offset);       // CFA = SP + 16
    *         DWRF_UV(16);
    *
    *         DWRF_U8(DWRF_CFA_offset | DWRF_REG_FP); // Save x29 (frame pointer)
    *         DWRF_UV(2);                             // At offset 2 * 8 = 16 bytes
    *
    *         DWRF_U8(DWRF_CFA_offset | DWRF_REG_RA); // Save x30 (return address)
    *         DWRF_UV(1);                             // At offset 1 * 8 = 8 bytes
    *
    *         DWRF_U8(DWRF_CFA_advance_loc | 3);      // Advance location by 3 units (3 * 4 = 12 bytes)
    *
    *         DWRF_U8(DWRF_CFA_offset | DWRF_REG_RA); // Restore x30
    *         DWRF_U8(DWRF_CFA_offset | DWRF_REG_FP); // Restore x29
    *
    *         DWRF_U8(DWRF_CFA_def_cfa_offset);       // CFA = SP
    *         DWRF_UV(0);
    *     )
    *
    * To regenerate:
    *   1. Get the `code alignment factor`, `data alignment factor`, and `RA column` from the CIE.
    *   2. Note the range of the function from the FDE's `pc=...` line and map it to the JIT code as
    *      the code is in a different address space every time.
    *   3. For each `DW_CFA_*` entry, use the corresponding `DWRF_*` macro:
    *        - `DW_CFA_def_cfa_offset`     → DWRF_U8(DWRF_CFA_def_cfa_offset), DWRF_UV(value)
    *        - `DW_CFA_offset: rX`         → DWRF_U8(DWRF_CFA_offset | reg), DWRF_UV(offset)
    *        - `DW_CFA_restore: rX`        → DWRF_U8(DWRF_CFA_offset | reg) // restore is same as reusing offset
    *        - `DW_CFA_advance_loc: N`     → DWRF_U8(DWRF_CFA_advance_loc | (N / code_alignment_factor))
    *   4. Use `DWRF_REG_FP`, `DWRF_REG_RA`, etc., for register numbers.
    *   5. Use `sizeof(uintptr_t)` (typically 8) for pointer size calculations and alignment.
    */

    /*
     * Emit DWARF EH CIE (Common Information Entry)
     *
     * The CIE describes the calling conventions and basic unwinding rules
     * that apply to all functions in this compilation unit.
     */
    DWRF_SECTION(CIE,
        DWRF_U32(0);                           // CIE ID (0 indicates this is a CIE)
        DWRF_U8(DWRF_CIE_VERSION);            // CIE version (1)
        DWRF_STR("zR");                       // Augmentation string ("zR" = has LSDA)
#ifdef __x86_64__
        DWRF_UV(1);                           // Code alignment factor (x86_64: 1 byte)
#elif defined(__aarch64__) && defined(__AARCH64EL__) && !defined(__ILP32__)
        DWRF_UV(4);                           // Code alignment factor (AArch64: 4 bytes per instruction)
#endif
        DWRF_SV(-(int64_t)sizeof(uintptr_t)); // Data alignment factor (negative)
        DWRF_U8(DWRF_REG_RA);                 // Return address register number
        DWRF_UV(1);                           // Augmentation data length
        DWRF_U8(DWRF_EH_PE_pcrel | DWRF_EH_PE_sdata4); // FDE pointer encoding

        /* Initial CFI instructions - describe default calling convention */
#ifdef __x86_64__
        /* x86_64 initial CFI state */
        DWRF_U8(DWRF_CFA_def_cfa);            // Define CFA (Call Frame Address)
        DWRF_UV(DWRF_REG_SP);                 // CFA = SP register
        DWRF_UV(sizeof(uintptr_t));           // CFA = SP + pointer_size
        DWRF_U8(DWRF_CFA_offset|DWRF_REG_RA); // Return address is saved
        DWRF_UV(1);                           // At offset 1 from CFA
#elif defined(__aarch64__) && defined(__AARCH64EL__) && !defined(__ILP32__)
        /* AArch64 initial CFI state */
        DWRF_U8(DWRF_CFA_def_cfa);            // Define CFA (Call Frame Address)
        DWRF_UV(DWRF_REG_SP);                 // CFA = SP register
        DWRF_UV(0);                           // CFA = SP + 0 (AArch64 starts with offset 0)
        // No initial register saves in AArch64 CIE
#endif
        DWRF_ALIGNNOP(sizeof(uintptr_t));     // Align to pointer boundary
    )

    ctx->eh_frame_p = p;  // Remember start of FDE data

    /*
     * Emit DWARF EH FDE (Frame Description Entry)
     *
     * The FDE describes unwinding information specific to this function.
     * It references the CIE and provides function-specific CFI instructions.
     *
     * The PC-relative offset is calculated after the entire EH frame is built
     * to ensure accurate positioning relative to the synthesized DSO layout.
     */
    DWRF_SECTION(FDE,
        DWRF_U32((uint32_t)(p - framep));     // Offset to CIE (backwards reference)
        ctx->fde_p = p;                        // Remember where PC offset field is located for later calculation
        DWRF_U32(0);                           // Placeholder for PC-relative offset (calculated at end of elf_init_ehframe)
        DWRF_U32(ctx->code_size);             // Address range covered by this FDE (code length)
        DWRF_U8(0);                           // Augmentation data length (none)

        /*
         * Architecture-specific CFI instructions
         *
         * These instructions describe how registers are saved and restored
         * during function calls. Each architecture has different calling
         * conventions and register usage patterns.
         */
#ifdef __x86_64__
        /* x86_64 calling convention unwinding rules with frame pointer */
#  if defined(__CET__) && (__CET__ & 1)
        DWRF_U8(DWRF_CFA_advance_loc | 4);    // Advance past endbr64 (4 bytes)
#  endif
        DWRF_U8(DWRF_CFA_advance_loc | 1);    // Advance past push %rbp (1 byte)
        DWRF_U8(DWRF_CFA_def_cfa_offset);     // def_cfa_offset 16
        DWRF_UV(16);                          // New offset: SP + 16
        DWRF_U8(DWRF_CFA_offset | DWRF_REG_BP); // offset r6 at cfa-16
        DWRF_UV(2);                           // Offset factor: 2 * 8 = 16 bytes
        DWRF_U8(DWRF_CFA_advance_loc | 3);    // Advance past mov %rsp,%rbp (3 bytes)
        DWRF_U8(DWRF_CFA_def_cfa_register);   // def_cfa_register r6
        DWRF_UV(DWRF_REG_BP);                 // Use base pointer register
        DWRF_U8(DWRF_CFA_advance_loc | 3);    // Advance past call *%rcx (2 bytes) + pop %rbp (1 byte) = 3
        DWRF_U8(DWRF_CFA_def_cfa);            // def_cfa r7 ofs 8
        DWRF_UV(DWRF_REG_SP);                 // Use stack pointer register
        DWRF_UV(8);                           // New offset: SP + 8
#elif defined(__aarch64__) && defined(__AARCH64EL__) && !defined(__ILP32__)
        /* AArch64 calling convention unwinding rules */
        DWRF_U8(DWRF_CFA_advance_loc | 1);        // Advance by 1 instruction (4 bytes)
        DWRF_U8(DWRF_CFA_def_cfa_offset);         // CFA = SP + 16
        DWRF_UV(16);                              // Stack pointer moved by 16 bytes
        DWRF_U8(DWRF_CFA_offset | DWRF_REG_FP);   // x29 (frame pointer) saved
        DWRF_UV(2);                               // At CFA-16 (2 * 8 = 16 bytes from CFA)
        DWRF_U8(DWRF_CFA_offset | DWRF_REG_RA);   // x30 (link register) saved
        DWRF_UV(1);                               // At CFA-8 (1 * 8 = 8 bytes from CFA)
        DWRF_U8(DWRF_CFA_advance_loc | 3);        // Advance by 3 instructions (12 bytes)
        DWRF_U8(DWRF_CFA_restore | DWRF_REG_RA);  // Restore x30 - NO DWRF_UV() after this!
        DWRF_U8(DWRF_CFA_restore | DWRF_REG_FP);  // Restore x29 - NO DWRF_UV() after this!
        DWRF_U8(DWRF_CFA_def_cfa_offset);         // CFA = SP + 0 (stack restored)
        DWRF_UV(0);                               // Back to original stack position
#else
#    error "Unsupported target architecture"
#endif

        DWRF_ALIGNNOP(sizeof(uintptr_t));     // Align to pointer boundary
    )

    ctx->p = p;  // Update context pointer to end of generated data

    /* Calculate and update the PC-relative offset in the FDE
     *
     * When perf processes the jitdump, it creates a synthesized DSO with this layout:
     *
     *     Synthesized DSO Memory Layout:
     *     ┌─────────────────────────────────────────────────────────────┐ < code_start
     *     │                        Code Section                         │
     *     │                    (round_up(code_size, 8) bytes)           │
     *     ├─────────────────────────────────────────────────────────────┤ < start of EH frame data
     *     │                      EH Frame Data                          │
     *     │  ┌─────────────────────────────────────────────────────┐    │
     *     │  │                 CIE data                            │    │
     *     │  └─────────────────────────────────────────────────────┘    │
     *     │  ┌─────────────────────────────────────────────────────┐    │
     *     │  │ FDE Header:                                         │    │
     *     │  │   - CIE offset (4 bytes)                            │    │
     *     │  │   - PC offset (4 bytes) <─ fde_offset_in_frame ─────┼────┼─> points to code_start
     *     │  │   - address range (4 bytes)                         │    │   (this specific field)
     *     │  │ CFI Instructions...                                 │    │
     *     │  └─────────────────────────────────────────────────────┘    │
     *     ├─────────────────────────────────────────────────────────────┤ < reference_point
     *     │                    EhFrameHeader                            │
     *     │                 (navigation metadata)                       │
     *     └─────────────────────────────────────────────────────────────┘
     *
     * The PC offset field in the FDE must contain the distance from itself to code_start:
     *
     *   distance = code_start - fde_pc_field
     *
     * Where:
     *   fde_pc_field_location = reference_point - eh_frame_size + fde_offset_in_frame
     *   code_start_location = reference_point - eh_frame_size - round_up(code_size, 8)
     *
     * Therefore:
     *   distance = code_start_location - fde_pc_field_location
     *            = (ref - eh_frame_size - rounded_code_size) - (ref - eh_frame_size + fde_offset_in_frame)
     *            = -rounded_code_size - fde_offset_in_frame
     *            = -(round_up(code_size, 8) + fde_offset_in_frame)
     *
     * Note: fde_offset_in_frame is the offset from EH frame start to the PC offset field,
     *
     */
    if (ctx->fde_p != NULL) {
        int32_t fde_offset_in_frame = (ctx->fde_p - ctx->startp);
        int32_t rounded_code_size = round_up(ctx->code_size, 8);
        int32_t pc_relative_offset = -(rounded_code_size + fde_offset_in_frame);


        // Update the PC-relative offset in the FDE
        *(int32_t*)ctx->fde_p = pc_relative_offset;
    }
}

// =============================================================================
//                              JITDUMP INITIALIZATION
// =============================================================================

/*
 * Initialize the perf jitdump interface
 *
 * This function sets up everything needed to generate jitdump files:
 * 1. Creates the jitdump file with a unique name
 * 2. Maps the first page to signal perf that we're using the interface
 * 3. Writes the jitdump header
 * 4. Initializes synchronization primitives
 *
 * The memory mapping is crucial - perf detects jitdump files by scanning
 * for processes that have mapped files matching the pattern /tmp/jit-*.dump
 *
 * Returns: Pointer to initialized state, or NULL on failure
 */
static void* perf_map_jit_init(void) {
    char filename[100];
    int pid = getpid();

    /* Create unique filename based on process ID */
    snprintf(filename, sizeof(filename) - 1, "/tmp/jit-%d.dump", pid);

    /* Create/open the jitdump file with appropriate permissions */
    const int fd = open(filename, O_CREAT | O_TRUNC | O_RDWR, 0666);
    if (fd == -1) {
        return NULL;  // Failed to create file
    }

    /* Get system page size for memory mapping */
    const long page_size = sysconf(_SC_PAGESIZE);
    if (page_size == -1) {
        close(fd);
        return NULL;  // Failed to get page size
    }

#if defined(__APPLE__)
    // On macOS, samply uses a preload to find jitdumps and this mmap can be slow.
    perf_jit_map_state.mapped_buffer = NULL;
#else
    /*
     * Map the first page of the jitdump file
     *
     * This memory mapping serves as a signal to perf that this process
     * is generating JIT code. Perf scans /proc/.../maps looking for mapped
     * files that match the jitdump naming pattern.
     *
     * The mapping must be PROT_READ | PROT_EXEC to be detected by perf.
     */
    perf_jit_map_state.mapped_buffer = mmap(
        NULL,                    // Let kernel choose address
        page_size,               // Map one page
        PROT_READ | PROT_EXEC,   // Read and execute permissions (required by perf)
        MAP_PRIVATE,             // Private mapping
        fd,                      // File descriptor
        0                        // Offset 0 (first page)
    );

    if (perf_jit_map_state.mapped_buffer == NULL) {
        close(fd);
        return NULL;  // Memory mapping failed
    }
#endif

    perf_jit_map_state.mapped_size = page_size;

    /* Convert file descriptor to FILE* for easier I/O operations */
    perf_jit_map_state.perf_map = fdopen(fd, "w+");
    if (perf_jit_map_state.perf_map == NULL) {
        close(fd);
        return NULL;  // Failed to create FILE*
    }

    /*
     * Set up file buffering for better performance
     *
     * We use a large buffer (2MB) because jitdump files can be written
     * frequently during program execution. Buffering reduces system call
     * overhead and improves overall performance.
     */
    setvbuf(perf_jit_map_state.perf_map, NULL, _IOFBF, 2 * MB);

    /* Write the jitdump file header */
    perf_map_jit_write_header(pid, perf_jit_map_state.perf_map);

    /*
     * Initialize thread synchronization lock
     *
     * Multiple threads may attempt to write to the jitdump file
     * simultaneously. This lock ensures thread-safe access to the
     * global jitdump state.
     */
    perf_jit_map_state.map_lock = PyThread_allocate_lock();
    if (perf_jit_map_state.map_lock == NULL) {
        fclose(perf_jit_map_state.perf_map);
        return NULL;  // Failed to create lock
    }

    /* Initialize code ID counter */
    perf_jit_map_state.code_id = 0;

    /* Calculate padding size based on actual unwind info requirements */
    size_t eh_frame_size = calculate_eh_frame_size();
    size_t unwind_data_size = sizeof(EhFrameHeader) + eh_frame_size;
    trampoline_api.code_padding = round_up(unwind_data_size, 16);
    trampoline_api.code_alignment = 32;

    return &perf_jit_map_state;
}

// =============================================================================
//                              MAIN JITDUMP ENTRY WRITING
// =============================================================================

/*
 * Write a complete jitdump entry for a Python function
 *
 * This is the main function called by Python's trampoline system whenever
 * a new piece of JIT-compiled code needs to be recorded. It writes both
 * the unwinding information and the code load event to the jitdump file.
 *
 * The function performs these steps:
 * 1. Initialize jitdump system if not already done
 * 2. Extract function name and filename from Python code object
 * 3. Generate DWARF unwinding information
 * 4. Write unwinding info event to jitdump file
 * 5. Write code load event to jitdump file
 *
 * Args:
 *   state: Jitdump state (currently unused, uses global state)
 *   code_addr: Address where the compiled code resides
 *   code_size: Size of the compiled code in bytes
 *   co: Python code object containing metadata
 *
 * IMPORTANT: This function signature is part of Python's internal API
 * and must not be changed without coordinating with core Python development.
 */
static void perf_map_jit_write_entry(void *state, const void *code_addr,
                                    unsigned int code_size, PyCodeObject *co)
{
    /* Initialize jitdump system on first use */
    if (perf_jit_map_state.perf_map == NULL) {
        void* ret = perf_map_jit_init();
        if(ret == NULL){
            return;  // Initialization failed, silently abort
        }
    }

    /*
     * Extract function information from Python code object
     *
     * We create a human-readable function name by combining the qualified
     * name (includes class/module context) with the filename. This helps
     * developers identify functions in perf reports.
     */
    const char *entry = "";
    if (co->co_qualname != NULL) {
        entry = PyUnicode_AsUTF8(co->co_qualname);
    }

    const char *filename = "";
    if (co->co_filename != NULL) {
        filename = PyUnicode_AsUTF8(co->co_filename);
    }

    /*
     * Create formatted function name for perf display
     *
     * Format: "py::<function_name>:<filename>"
     * The "py::" prefix helps identify Python functions in mixed-language
     * profiles (e.g., when profiling C extensions alongside Python code).
     */
    size_t perf_map_entry_size = snprintf(NULL, 0, "py::%s:%s", entry, filename) + 1;
    char* perf_map_entry = (char*) PyMem_RawMalloc(perf_map_entry_size);
    if (perf_map_entry == NULL) {
        return;  // Memory allocation failed
    }
    snprintf(perf_map_entry, perf_map_entry_size, "py::%s:%s", entry, filename);

    const size_t name_length = strlen(perf_map_entry);
    uword base = (uword)code_addr;
    uword size = code_size;

    /*
     * Generate DWARF unwinding information
     *
     * DWARF data is essential for proper stack unwinding during profiling.
     * Without it, perf cannot generate accurate call graphs, especially
     * in optimized code where frame pointers may be omitted.
     */
    ELFObjectContext ctx;
    char buffer[1024];  // Buffer for DWARF data (1KB should be sufficient)
    ctx.code_size = code_size;
    ctx.startp = ctx.p = (uint8_t*)buffer;
    ctx.fde_p = NULL;  // Initialize to NULL, will be set when FDE is written

    /* Generate EH frame (Exception Handling frame) data */
    elf_init_ehframe(&ctx);
    int eh_frame_size = ctx.p - ctx.startp;

    /*
     * Write Code Unwinding Information Event
     *
     * This event must be written before the code load event to ensure
     * perf has the unwinding information available when it processes
     * the code region.
     */
    CodeUnwindingInfoEvent ev2;
    ev2.base.event = PerfUnwindingInfo;
    ev2.base.time_stamp = get_current_monotonic_ticks();
    ev2.unwind_data_size = sizeof(EhFrameHeader) + eh_frame_size;

    /* Verify we don't exceed our padding budget */
    assert(ev2.unwind_data_size <= (uint64_t)trampoline_api.code_padding);

    ev2.eh_frame_hdr_size = sizeof(EhFrameHeader);
    ev2.mapped_size = round_up(ev2.unwind_data_size, 16);  // 16-byte alignment

    /* Calculate total event size with padding */
    int content_size = sizeof(ev2) + sizeof(EhFrameHeader) + eh_frame_size;
    int padding_size = round_up(content_size, 8) - content_size;  // 8-byte align
    ev2.base.size = content_size + padding_size;

    /* Write the unwinding info event header */
    perf_map_jit_write_fully(&ev2, sizeof(ev2));

    /*
     * Write EH Frame Header
     *
     * The EH frame header provides metadata about the DWARF unwinding
     * information that follows. It includes pointers and counts that
     * help perf navigate the unwinding data efficiently.
     */
    EhFrameHeader f;
    f.version = 1;
    f.eh_frame_ptr_enc = DwarfSData4 | DwarfPcRel;  // PC-relative signed 4-byte
    f.fde_count_enc = DwarfUData4;                  // Unsigned 4-byte count
    f.table_enc = DwarfSData4 | DwarfDataRel;       // Data-relative signed 4-byte

    /* Calculate relative offsets for EH frame navigation */
    f.eh_frame_ptr = -(eh_frame_size + 4 * sizeof(unsigned char));
    f.eh_fde_count = 1;  // We generate exactly one FDE per function
    f.from = -(round_up(code_size, 8) + eh_frame_size);

    int cie_size = ctx.eh_frame_p - ctx.startp;
    f.to = -(eh_frame_size - cie_size);

    /* Write EH frame data and header */
    perf_map_jit_write_fully(ctx.startp, eh_frame_size);
    perf_map_jit_write_fully(&f, sizeof(f));

    /* Write padding to maintain alignment */
    char padding_bytes[] = "\0\0\0\0\0\0\0\0";
    perf_map_jit_write_fully(&padding_bytes, padding_size);

    /*
     * Write Code Load Event
     *
     * This event tells perf about the new code region. It includes:
     * - Memory addresses and sizes
     * - Process and thread identification
     * - Function name for symbol resolution
     * - The actual machine code bytes
     */
    CodeLoadEvent ev;
    ev.base.event = PerfLoad;
    ev.base.size = sizeof(ev) + (name_length+1) + size;
    ev.base.time_stamp = get_current_monotonic_ticks();
    ev.process_id = getpid();
#if defined(__APPLE__)
    pthread_threadid_np(NULL, &ev.thread_id);
#else
    ev.thread_id = syscall(SYS_gettid);  // Get thread ID via system call
#endif
    ev.vma = base;                       // Virtual memory address
    ev.code_address = base;              // Same as VMA for our use case
    ev.code_size = size;

    /* Assign unique code ID and increment counter */
    perf_jit_map_state.code_id += 1;
    ev.code_id = perf_jit_map_state.code_id;

    /* Write code load event and associated data */
    perf_map_jit_write_fully(&ev, sizeof(ev));
    perf_map_jit_write_fully(perf_map_entry, name_length+1);  // Include null terminator
    perf_map_jit_write_fully((void*)(base), size);           // Copy actual machine code

    /* Clean up allocated memory */
    PyMem_RawFree(perf_map_entry);
}

// =============================================================================
//                              CLEANUP AND FINALIZATION
// =============================================================================

/*
 * Finalize and cleanup the perf jitdump system
 *
 * This function is called when Python is shutting down or when the
 * perf trampoline system is being disabled. It ensures all resources
 * are properly released and all buffered data is flushed to disk.
 *
 * Args:
 *   state: Jitdump state (currently unused, uses global state)
 *
 * Returns: 0 on success
 *
 * IMPORTANT: This function signature is part of Python's internal API
 * and must not be changed without coordinating with core Python development.
 */
static int perf_map_jit_fini(void* state) {
    /*
     * Close jitdump file with proper synchronization
     *
     * We need to acquire the lock to ensure no other threads are
     * writing to the file when we close it. This prevents corruption
     * and ensures all data is properly flushed.
     */
    if (perf_jit_map_state.perf_map != NULL) {
        PyThread_acquire_lock(perf_jit_map_state.map_lock, 1);
        fclose(perf_jit_map_state.perf_map);  // This also flushes buffers
        PyThread_release_lock(perf_jit_map_state.map_lock);

        /* Clean up synchronization primitive */
        PyThread_free_lock(perf_jit_map_state.map_lock);
        perf_jit_map_state.perf_map = NULL;
    }

    /*
     * Unmap the memory region
     *
     * This removes the signal to perf that we were generating JIT code.
     * After this point, perf will no longer detect this process as
     * having JIT capabilities.
     */
    if (perf_jit_map_state.mapped_buffer != NULL) {
        munmap(perf_jit_map_state.mapped_buffer, perf_jit_map_state.mapped_size);
        perf_jit_map_state.mapped_buffer = NULL;
    }

    /* Clear global state reference */
    trampoline_api.state = NULL;

    return 0;  // Success
}

// =============================================================================
//                              PUBLIC API EXPORT
// =============================================================================

/*
 * Python Perf Callbacks Structure
 *
 * This structure defines the callback interface that Python's trampoline
 * system uses to integrate with perf profiling. It contains function
 * pointers for initialization, event writing, and cleanup.
 *
 * CRITICAL: This structure and its contents are part of Python's internal
 * API. The function signatures and behavior must remain stable to maintain
 * compatibility with the Python interpreter's perf integration system.
 *
 * Used by: Python's _PyPerf_Callbacks system in pycore_ceval.h
 */
_PyPerf_Callbacks _Py_perfmap_jit_callbacks = {
    &perf_map_jit_init,        // Initialization function
    &perf_map_jit_write_entry, // Event writing function
    &perf_map_jit_fini,        // Cleanup function
};

#endif /* PY_HAVE_PERF_TRAMPOLINE */
